KR20140009908A - Covering layer for solar cell - Google Patents

Abstract

A module 1 having at least one solar cell 3 arranged on a carrier 2 comprises a cover layer 4 having side lugs 5 and corner lugs 6 provided in contact with each other on the back of the carrier. It includes.

Description

Cover layer for solar cell {COVERING LAYER FOR SOLAR CELL}

The present invention starts with a module having a solar cell disposed on a cover layer and a carrier according to the preamble of claim 1.

Solar modules with solar cells arranged on a carrier are often covered with a cover layer to protect the solar cells from moisture and moisture.

In particular, due to the effects of mechanical stress and weather, the cover layer may loosen from the carrier on the side and moisture may penetrate between the cover layer and the carrier and damage the solar cell.

The stresses mentioned are specifically caused by moving the carrier and the solar cell horizontally and vertically relative to one another, in particular due to the different linear coefficients of thermal expansion. This stress occurs especially during exothermic heat, due to heat generated by the solar cell itself, and at low outdoor temperatures.

Furthermore, the exposure of chemical and / or physical bonds between the cover layer and the carrier to external influences such as climate and UV radiation is particularly damaging over time due to these effects because the cover layer is generally transparent to UV. To be.

It is an object of the present invention to improve the above mentioned type of module by minimizing the loosening of the cover layer applied to the carrier to minimize the penetration of moisture.

This is achieved according to the invention by the features of claim 1.

The core of the invention is therefore that in a module having a cover layer applied to the side of the solar cell opposite to the carrier and at least one solar cell disposed on the carrier, the cover layer is a side lug, a corner lug. ) And a notch. In this design, the notch forms one side edge of the side lugs or one side edge of the corner lugs. The side lugs and corner lugs are separated by corresponding fold lines and are arranged on the side of the carrier opposite the solar cell, where the side edges of the corresponding side lugs and the corner lugs formed by the notches are in contact with each other. The side lugs of the cover layer and the corner lugs of the cover layer are part of the cover layer. They are thus made of the same material and are made when producing the cover layer, for example by removing or cutting the material to form a notch.

This is advantageous in that the side lugs and corner lugs significantly lengthen the diffusion path into the solar cell of moisture that penetrates between the cover layer and the carrier.

Another improvement is that the side edges of the corresponding side lugs and the corner lugs are in contact with each other to further prevent the penetration of moisture.

Due to the corner lugs and the lateral arrangement on the side of the carrier opposite the solar cell, the bond is protected from external influences such as weather, UV radiation and especially direct rain water.

It is particularly suitable along the total side edges of the side lugs, in particular when the side edges of the corner lugs overlap with the corresponding side edges of the adjacent side lugs. This results in a significant increase in the diffusion path into the solar cell for the penetration of the liquid in the overlap region.

The folding line of the corner lug is more advantageously intersecting with the folding line of the side lug 3-15 mm away from the point of contact of the corresponding side lug and the side edge of the corner lug, in particular adjacent to the position of the side lug folding line. This results in a significant increase in the diffusion path to the solar cell for penetration of the liquid in the cutting region of the fold line.

Other advantageous embodiments of the invention are indicated in the dependent claims.

Hereinafter, embodiments of the present invention will be described in detail using the drawings. Like elements are referred to by like reference numerals in the various figures.
1 is a cross-sectional view of a module of the prior art;
2 to 3 are cross-sectional views of modules according to the invention;
4a to 7b are plan views of the carrier side opposite the solar cell in the module according to the invention before and after applying the side lugs and the corner lugs to the carrier.
Only elements essential to the instant understanding of the invention are shown.

1 shows a cross section of a module of the prior art, which module has a cover layer 4 applied over the solar cell 3 and bonded to the carrier 2.

2 shows a cross-sectional view of the module 1 according to the invention with the cover layer 4 arranged above the side lug 5 on the side of the carrier 2 opposite the solar cell 3. 3 shows a variant of FIG. 2 with the cover layer folded laterally over itself. This makes the sealing of the carrier and the solar cell with the cover layer as easy as possible.

2 and 3 show a significantly longer volcanic path for the infiltration of liquid 10 compared to FIG. 1. In the drawing according to the invention, in order to reach the solar cell 3, the penetrating liquid overcomes contact between the side lug 5 and the carrier 2 on the one hand and on the other hand the side of the carrier on the solar cell side. The contact of the cover layer 4 must be overcome.

4a shows a plan view of the carrier side opposite the solar cell in the module according to the invention before applying the side lugs and the corner lugs to the carrier. In FIG. 4B, the corner lug 6 is already folded at the fold line 9 and is positioned above the carrier 2. 4C shows the module after folding the side lugs at the corresponding folding line. The side lugs 5 and the side edges 8 of the corner lugs 6 formed by the notches 7 lie at the same height adjacent to each other on the carrier in FIG. 4c and thereby contact each other. This protects them from the ingress of moisture in the area of the side edge between the side of the carrier and the cover layer opposite the solar cell.

5A and 5B show a preferred embodiment. Figure 5a again shows a top view of the side of the carrier opposite the solar cell in the module according to the invention before applying the side lugs and corner lugs to the carrier. 5B shows the module after folding the side lugs and corner lugs over the corresponding fold lines. It is also clear that the side edges of the corner lugs overlap with the corresponding side edges of the adjacent side lugs, especially along the total side edges of the side lugs. This results in an additional increase in the diffusion path through which liquid penetrates into the solar cell in the overlap region. Of course, for the reasons described above it may also be advantageous for the side edges of the side lugs to overlap with the corresponding side edges of the adjacent corner lugs, especially along the total side edges of the corner lugs.

6A and 6B show another embodiment. 6a also shows the side lugs 5 and the corner lugs 6 before applying to the carrier 2. The notch 7 entails a real incision in the covering layer up to the folding line 9 of the corner lugs and side lugs, forming a notch without removal of material from the covering layer, thereby forming side edges of adjacent side lugs and corner lugs. (8) is formed. Preferably, however, the notch represents an angle of 5 to 45 ° measured by confinement to two adjacent side edges 8 from the fold line of the adjacent side edges. 6B shows the module after folding the second side lug over the first side lug and then folding the corner lug over it. The corresponding side edges are also superimposed here by corner lugs, especially along the total side edges of the side lugs. This results in the advantages already mentioned in FIG. 5C.

A more preferred embodiment of the present invention is shown in Figures 7a and 7b. FIG. 7A corresponds to FIG. 5A after folding the side lugs around the fold line 93. The dashed fold line 91 shows the arrangement of the fold line of the corner lugs 6 used in FIG. 5B, while the fold line 92 of the corner lugs intersects the fold line 93 of the adjacent side lugs. Preferably, the fold line of the corner lug intersects the fold line of the side lug at a position 3 to 15 mm measured from the contact point of the corresponding side lug 5 and the side edge 8 of the corner lug 6. This distance 12 is thus preferably from 3 to 15 mm as described above.

In FIG. 7B, the arrangement of the corner lugs shown in FIG. 5C is shown in dashed lines. The contact point 11 where the notch 7 meets the fold line 9 or is covered by the side edges 8 of the corresponding side and corner lugs is easy for liquid to penetrate. The diffusion path for the penetration of liquid towards the solar cell is further increased by moving the folding line of the corner lug in the direction of the center point of the carrier as shown by moving the folding line 91 towards the folding line 92. .

Furthermore, it may be advantageous for the fold line 9 to exhibit a distance of at least 2 to 10 mm from the carrier 2. This is advantageous for manufacturing engineering.

The cover layer 4 and the carrier 2, in particular the side lugs 5, the side lugs 6 and the sides of the carrier 2 opposite the solar cell 3 can be directly joined to one another. By "directly bonded" it is understood that no two layers or materials are present between the two materials and the two materials are directly connected to each other, preferably attached to each other.

This may in particular result in that direct bonding in manufacture can be achieved by the action of heat, pressure, physical absorption or any other physical force. This has the advantage in particular that no chemical bonding by the adhesive is required and this provides an advantageous effect on the manufacturing cost of the module 1.

However, there is a possibility that the cover layer 4 and the carrier, in particular the side lug 5 and the corner lug 6 and the side of the carrier 2 opposite to the solar cell 3 are joined by an adhesive layer. The adhesive used for this adhesive layer may be, for example, a contact adhesive and / or a hot melt adhesive. This ensures good bonding and additional protection from the ingress of moisture.

Contact and hot melt adhesives are generally known to those skilled in the art and are described in CD Roempp Chemie Lexikon [ Encyclopedia of Chemistry ] (1995), Georg Thieme Verlag: Stuttgart, Version 1.0. .

Preferably, the adhesive carries an adhesive selected from the group consisting of ethylene / vinyl acetate copolymers (EVA), olefinic crosslinkable thermoplastic elastomers, acrylate compounds, polyurethane polymers, and silane-terminated polymers.

Preferred acrylate compounds are especially acrylate compounds of acrylic monomers, in particular of acrylic and methacrylic acid esters.

The term "polyurethane polymer" includes all polymers prepared according to the so-called diisocyanate polyadditions method. It also includes polymers with little or no urethane groups. Examples of polyurethane polymers are polyether polyurethanes, polyester polyurethanes, polyether polyresins, polyresins, polyester polyresins, polyisocyanurates and polycarbodiimides.

Particularly preferred as an adhesive is ethylene / vinyl acetate copolymer (EVA).

In particular when the adhesive also binds the cover layer 4 to the solar cell 3, an adhesive which is characterized by high UV stability with high transmittance in the spectral range of the present solar cell is more preferred.

In general, the cover layer 4 is accompanied by a layer made of plastic which is characterized by high transmittance in the spectral range of the current solar cell.

Preferably the transmittance of the covering layer material measured as having a covering layer thickness of 0.1 mm in the spectrum of 300 to 1300 nm amounts to more than 85%, in particular more than 90%, particularly preferably more than 93%.

Suitable materials for the capping layer are, for example, copolymers of ethylene and tetrafluoroethylene sold by DuPont Corporation under the trade name Tefzel® or by DuPont Corporation under the trade name Tedlar®. Fluoropolymers such as polyvinylidene fluoride.

Such a cover layer is advantageous in that it can protect the solar cell from the penetration, damage and contamination of the liquid.

The cover layer generally exhibits a thickness of 0.01 to 0.1 mm, preferably 0.02 to 0.05 mm.

The term "solar cell" is understood herein to refer to both individual solar cell units and to a plurality of solar cell units that are electrically and / or mechanically connected. Such solar cell units include, for example, Clean Venture 21 (Japan); Fuji Electric (Japan); United Solar Ovonic LLC (United States); Helianthos BV (Netherlands); VHF-Flexcell (Switzerland); And Ascent Solar (USA).

The term "solar cell unit" in this document refers to a semiconductor comprising a pn junction that converts sunlight directly into electrical energy as described in CD Roempp Chemie Lexikon (1995), Georg Thieme Verlag: Stuttgart, Version 1.0. It is understood to be a part.

The carriers mentioned generally carry a flexible carrier made of metal or plastic, preferably made of corrosion resistant steel or aluminum alloy.

Of course, the invention is not limited to the embodiments shown and described.

1: module 2: carrier
3: solar cell 4: cover layer
5: side lug 6: corner lug
7: notch 8: side edge
9: folding line 10: penetration moisture
11: contact point of side edge 12: distance

Claims (4)

Module (1) comprising at least one solar cell (3) disposed on a carrier (2) and a cover layer (4) applied to the side of the solar cell (3) opposite the carrier (2) )as,
The cover layer 4 has side lugs 5, corner lugs 6 and notches 7, one notch 7 each having side lugs 5. ) And the side edges 8 of the corner lugs 6, the side lugs 5 and the corner lugs 6 being separated by corresponding fold lines 9 so as to be opposite to the solar cell 3. A module (1) characterized in that it is arranged on the side of the carrier (2) and the corresponding side lugs (5) formed by the notches (7) and the side edges of the corner lugs (6) are in contact with each other. The side edge 8 of claim 1, wherein the side edge 8 of the corner lug 6, in particular along the total side edge of the side lug 5, of the corresponding side edge 8 of the adjacent side lug 5. Module (1), characterized in that overlapping with. The folding line 9 of the corner lug 6 is in particular the contact point 11 of the corresponding side lug 5 and the side edge 8 of the corner lug 6. Module (1) characterized in that it intersects the fold line (9) of adjacent side lugs (5) at a position on the fold line of the side lug, measured 3 to 15 mm apart. The module (1) according to any one of the preceding claims, characterized in that the fold line (9) exhibits a distance of at least 2 to 10 mm from the carrier (2).

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